Acoustic filtering of particles in a flow regime

2014 IEEE International Ultrasonics Symposium Pub Date : 2014-10-23 DOI:10.1109/ULTSYM.2014.0355

Kristoffer Johansen, Torstein Yddal, S. Kotopoulis, M. Postema

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Abstract

Hydroelectric power is a clean source of energy, providing up to 20% of the World's electricity. Nevertheless, hydroelectric power plants are plagued with a common problem: silt. The silt causes damage to turbine blades, which then require repairing or replacing. In this study, we investigated the possibility to filter micron-sized particles from water using ultrasound. We designed a custom-made flow chamber and performed flow simulations and experiments to evaluate its efficacy. We used a 195-kHz ultrasound transducer operating in continuous-wave mode with acoustic output powers up to 12W. Our acoustic simulations showed that it should be possible to force a 200-μm particle over 2cm in flow, using an acoustic pressure of 12 MPa. Our flow simulations showed, that the fluid flow is not drastically decreased with the flow chamber, which was validated by the experimental measurements. The flow was not reduced when the ultrasound was activated. The acoustic filtering was effective between acoustic powers of 2.6 and 6.4W, where the particle concentration in the clean output was statistically significantly lower than the null experiments.

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流态中粒子的声波过滤

水力发电是一种清洁能源，提供了世界上20%的电力。然而，水力发电厂面临着一个共同的问题:淤泥。淤泥会损坏涡轮叶片，需要修理或更换。在这项研究中，我们研究了利用超声波从水中过滤微米级颗粒的可能性。我们设计了一个定制的流动室，并进行了流动模拟和实验来评估其效果。我们使用了一个195 khz的超声换能器，工作在连续波模式下，声输出功率高达12W。我们的声学模拟表明，使用12 MPa的声压，应该可以迫使200 μm的颗粒在2cm以上流动。流动模拟结果表明，流体的流量并没有随着流室的增加而急剧减小，实验结果也验证了这一点。当超声波被激活时，流量没有减少。在声功率为2.6 ~ 6.4W时，滤除效果良好，且净输出中颗粒浓度明显低于零实验。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2014 IEEE International Ultrasonics Symposium

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